Abstract: Methods for reducing leakage currents through unselected memory cells of a memory array during a memory operation are described. In some cases, the leakage currents through the unselected memory cells of the memory array may be reduced by setting an adjustable resistance bit line structure connected to the unselected memory cells into a non-conducting state. The adjustable resistance bit line structure may comprise a bit line structure in which the resistance of an intrinsic (or near intrinsic) polysilicon portion of the bit line structure may be adjusted via an application of a voltage to a select gate portion of the bit line structure that is not directly connected to the intrinsic polysilicon portion. The intrinsic polysilicon portion may be set into a conducting state or a non-conducting state based on the voltage applied to the select gate portion.

Abstract: Methods for reducing leakage currents through unselected memory cells of a memory array during a memory operation are described. In some cases, the leakage currents through the unselected memory cells of the memory array may be reduced by setting an adjustable resistance bit line structure connected to the unselected memory cells into a non-conducting state. The adjustable resistance bit line structure may comprise a bit line structure in which the resistance of an intrinsic (or near intrinsic) polysilicon portion of the bit line structure may be adjusted via an application of a voltage to a select gate portion of the bit line structure that is not directly connected to the intrinsic polysilicon portion. The intrinsic polysilicon portion may be set into a conducting state or a non-conducting state based on the voltage applied to the select gate portion.

Abstract: Methods for reducing leakage currents through unselected memory cells of a memory array during a memory operation are described. In some cases, the leakage currents through the unselected memory cells of the memory array may be reduced by setting an adjustable resistance bit line structure connected to the unselected memory cells into a non-conducting state. The adjustable resistance bit line structure may comprise a bit line structure in which the resistance of an intrinsic (or near intrinsic) polysilicon portion of the bit line structure may be adjusted via an application of a voltage to a select gate portion of the bit line structure that is not directly connected to the intrinsic polysilicon portion. The intrinsic polysilicon portion may be set into a conducting state or a non-conducting state based on the voltage applied to the select gate portion.

Abstract: Methods for reducing leakage currents through unselected memory cells of a memory array during a memory operation are described. In some cases, the leakage currents through the unselected memory cells of the memory array may be reduced by setting an adjustable resistance bit line structure connected to the unselected memory cells into a non-conducting state. The adjustable resistance bit line structure may comprise a bit line structure in which the resistance of an intrinsic (or near intrinsic) polysilicon portion of the bit line structure may be adjusted via an application of a voltage to a select gate portion of the bit line structure that is not directly connected to the intrinsic polysilicon portion. The intrinsic polysilicon portion may be set into a conducting state or a non-conducting state based on the voltage applied to the select gate portion.

Abstract: Methods for reducing leakage currents through unselected memory cells of a memory array during a memory operation are described. In some cases, the leakage currents through the unselected memory cells of the memory array may be reduced by setting an adjustable resistance bit line structure connected to the unselected memory cells into a non-conducting state. The adjustable resistance bit line structure may comprise a bit line structure in which the resistance of an intrinsic (or near intrinsic) polysilicon portion of the bit line structure may be adjusted via an application of a voltage to a select gate portion of the bit line structure that is not directly connected to the intrinsic polysilicon portion. The intrinsic polysilicon portion may be set into a conducting state or a non-conducting state based on the voltage applied to the select gate portion.

Abstract: A skin marking device that can be used in radiographic imaging comprising a platform having a handle, a marking member that extends from the handle over the platform, and radiographic markings. The platform has an opening that one end of the marking member is positioned over. The marking member also has a marking pad deployed on that end. When the marking member is depressed, at least a portion of the marking member extends into the opening in the platform allowing the marking pad to protrude from the opposite side of the platform. In use, the device is placed on or near a patient's skin during radiographic imaging and the radiopaque markings are used to assist in proper placement of the device. Once proper placement is achieved, the marking member is depressed, which presses the marking pad through the opening to mark the patient's skin at the desired location.

Abstract: A skin marking device that can be used in radiographic imaging comprising a platform having a handle, a marking member that extends from the handle over the platform, and radiographic markings. The platform has an opening that one end of the marking member is positioned over. The marking member also has a marking pad deployed on that end. When the marking member is depressed, at least a portion of the marking member extends into the opening in the platform allowing the marking pad to protrude from the opposite side of the platform. In use, the device is placed on or near a patient's skin during radiographic imaging and the radiopaque markings are used to assist in proper placement of the device. Once proper placement is achieved, the marking member is depressed, which presses the marking pad through the opening to mark the patient's skin at the desired location.

Abstract: A vertical NAND string device includes a semiconductor channel, where at least one end portion of the semiconductor channel extends substantially perpendicular to a major surface of a substrate, at least one semiconductor or electrically conductive landing pad embedded in the semiconductor channel, a tunnel dielectric located adjacent to the semiconductor channel, a charge storage region located adjacent to the tunnel dielectric, a blocking dielectric located adjacent to the charge storage region and a plurality of control gate electrodes extending substantially parallel to the major surface of the substrate.

Abstract: A vertical NAND string device includes a semiconductor channel, where at least one end portion of the semiconductor channel extends substantially perpendicular to a major surface of a substrate, at least one semiconductor or electrically conductive landing pad embedded in the semiconductor channel, a tunnel dielectric located adjacent to the semiconductor channel, a charge storage region located adjacent to the tunnel dielectric, a blocking dielectric located adjacent to the charge storage region and a plurality of control gate electrodes extending substantially parallel to the major surface of the substrate.

Abstract: A method of forming a memory cell is provided. The method includes forming a first pillar-shaped element that includes a first semiconductor material, forming a first opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the first opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided.

Abstract: A method of forming a memory cell is provided, the method including forming a first pillar-shaped element comprising a first semiconductor material, forming a first mold comprising an opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided.

Abstract: A method of forming a memory cell is provided, the method including forming a first pillar-shaped element comprising a first semiconductor material, forming a first mold comprising an opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided.

Abstract: A method of forming a three-dimensional, non-volatile memory array utilizing damascene fabrication techniques is disclosed. A bottom set of conductors is formed and a set of first pillar shaped elements of heavily doped semiconductor material as formed thereon. A mold is formed of insulating material having pillar shaped openings self-aligned with the first pillar shaped elements and a second semiconductor is deposited over the mold to form second pillar shaped elements aligned with the first pillar shaped elements. The pillar elements formed may be further processed by forming another mold of insulating material having trench openings aligned with the pillar shaped elements and then filling the trenches with conductive material to form conductors coupled to the pillar shaped elements.

Abstract: There is provided a monolithic three dimensional TFT mask ROM array. The array includes a plurality of device levels. Each of the plurality of device levels contains a first set of enabled TFTs and a second set of partially or totally disabled TFTs.

Abstract: A three-dimensional flash memory array incorporates thin film transistors having a charge storage dielectric arranged in series-connected NAND strings to achieve a 4F2 memory cell layout. The memory array may be programmed and erased using only tunneling currents, and no leakage paths are formed through non-selected memory cells. Each NAND string includes two block select devices for respectively coupling one end of the NAND string to a global bit line, and the other end to a shared bias node. Pairs of NAND strings within a block share the same global bit line. The memory cells are preferably depletion mode SONOS devices, as are the block select devices. The memory cells may be programmed to a near depletion threshold voltage, and the block select devices are maintained in a programmed state having a near depletion mode threshold voltage. NAND strings on more than one layer may be connected to global bit lines on a single layer.

Abstract: A method of forming a three-dimensional, non-volatile memory array utilizing damascene fabrication techniques is disclosed. A bottom set of conductors is formed and a set of first pillar shaped elements of heavily doped semiconductor material as formed thereon. A mold is formed of insulating material having pillar shaped openings self-aligned with the first pillar shaped elements and a second semiconductor is deposited over the mold to form second pillar shaped elements aligned with the first pillar shaped elements. The pillar elements formed may be further processed by forming another mold of insulating material having trench openings aligned with the pillar shaped elements and then filling the trenches with conductive material to form conductors coupled to the pillar shaped elements.

Abstract: A method of operating a nonvolatile memory cell includes providing the nonvolatile memory cell comprising a diode which is fabricated in a first resistivity, unprogrammed state, and applying a forward bias to the diode having a magnitude greater than a minimum voltage required for programming the diode to switch the diode to a second resistivity, programmed state. The second resistivity state is lower than the first resistivity state.

Abstract: There is provided a monolithic three dimensional TFT mask ROM array. The array includes a plurality of device levels. Each of the plurality of device levels contains a first set of enabled TFTs and a second set of partially or totally disabled TFTs.

Abstract: A nonvolatile memory cell comprising a diode formed of semiconductor material can store memory states by changing the resistance of the semiconductor material by application of a set pulse (decreasing resistance) or a reset pulse (increasing resistance.) In preferred embodiments, set pulses are applied with the diode under forward bias, while reset pulses are applied with the diode in reverse bias. By switching resistivity of the semiconductor material of the diode, a memory cell can be either one-time programmable or rewriteable, and can achieve two, three, four, or more distinct data states.

Abstract: An integrated circuit is provided including at least one memory cell. Such memory cell, in turn, includes a transistor and a capacitor. The transistor includes a source, a drain, and a gate. Further, the capacitor includes a well and a gate. The gate of the transistor remains in communication with the gate of the capacitor. In various other embodiments, the memory cell includes a transistor and a capacitor including wells of differing types (e.g. P-type, N-type). In such embodiments, the well of the transistor abuts the well of the capacitor. In still further embodiments, for a more compact design, a diffusion region of the transistor is situated less than 2.5 ?m from a diffusion region of the capacitor.